A method of preventing separation of a feedwater sparger end bracket assembly comprises installing first and second clamp members of a clamp over a feedwater sparger end bracket assembly in opposition to one another, and leaving the clamp in place to constrain the feedwater sparger end bracket assembly against separation in first, second and third directions.
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14. A method of preventing separation of a feedwater sparger end bracket assembly connected to a conduit of a feedwater sparger at a sparger/bracket junction within a boiling water reactor vessel, said method comprising the steps of
separating a one piece upper clamp member of a clamp from a one piece lower clamp member of the clamp, wherein the upper and lower clamp members each have opposed internal walls defining internal compartment therein, the feedwater sparger comprises an end plate attached to an end of the conduit, and the feedwater sparger end bracket assembly comprises an attachment plate connected to the end plate;
locating the internal compartment of the upper clamp member over a top portion of the attachment plate and a top portion of the end plate;
locating the internal compartment of the lower clamp member over a bottom portion of the attachment plate and a bottom portion of the end plate;
moving the upper and lower clamp members toward one another to confine the top portions of the attachment plate and the end plate together between the opposed internal walls of the upper clamp member and to confine the bottom portions of the attachment plate and the end plate together between the opposed internal walls of the lower clamp member;
securing the upper and lower clamp members to one another over the feedwater sparger end bracket assembly; and
leaving the upper and lower clamp members in place in the boiling water reactor vessel to prevent separation of the feedwater sparger end bracket assembly and to prevent separation of the feedwater sparger end bracket assembly from the feedwater sparger.
1. A method of preventing separation of a feedwater sparger end bracket assembly connected to a conduit of a feedwater sparger at a sparger/bracket junction within a boiling water reactor vessel, said method comprising the steps of
vertically separating an upper clamp member of a clamp from a lower clamp member of the clamp, wherein the upper and lower clamp members each have an internal compartment dispose entirely therein;
locating the upper clamp member over a top of the feedwater sparger end bracket assembly, wherein the feedwater sparger end bracket assembly includes an attachment plate, the feedwater sparger includes an end plate connected to a terminal end of the conduit and to the attachment plate, and the sparger/bracket junction is comprised of the attachment plate and the end plate connected thereto;
locating the lower clamp member over a bottom of the feedwater sparger end bracket assembly;
moving the upper and lower clamp members toward one another to position an upper portion of the sparger/bracket junction within a the compartment of the upper clamp member and to position a lower portion of the sparger/bracket junction within the compartment of the lower clamp member;
securing the upper and lower clamp members to one another over the feedwater sparger end bracket assembly with the upper and lower portions of the sparger/bracket junction positioned respectively with the compartments of the upper and lower clamp members; and
leaving the upper and lower clamp members in place in the boiling water reactor vessel to prevent separation of the feedwater sparger end bracket assembly and to prevent separation of the feedwater sparger end bracket assembly from the feedwater sparger along the sparger/bracket junction.
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This application is a divisional of U.S. patent application Ser. No. 10/059,044 filed Jan. 30, 2002, now abandoned, which claims priority from prior provisional patent application Ser. No. 60/264,965 filed Jan. 30, 2001, the entire disclosures of which are incorporated herein by reference.
1. Field of the Invention
The present invention relates to feedwater spargers in boiling water reactors and, more particularly, to clamps for the end bracket assemblies of feedwater spargers and to methods of preventing separation of feedwater sparger end bracket assemblies.
2. Brief Discussion of the Related Art
Conventional boiling water reactors typically include a reactor vessel, a shroud disposed within the reactor vessel and a fuel assembly within the shroud. Feedwater enters the reactor vessel via a feedwater inlet or nozzle and is distributed circumferentially within the reactor vessel by a feedwater sparger disposed in the reactor vessel between the shroud and the reactor vessel wall. The feedwater sparger comprises a ring-shaped pipe or conduit for carrying the feedwater and having an end attached to a sparger end plate via a feedwater sparger end weld, the sparger end plate and conduit end attached thereto defining an end of the feedwater sparger. A feedwater sparger end bracket assembly couples the end of the feedwater sparger to the reactor vessel wall in spaced relation therewith. The feedwater sparger end bracket assembly normally comprises an attachment plate connected to the sparger end plate via a weld, and the structural components of the feedwater sparger end bracket assembly are ordinarily connected to one another via one or more additional welds. The attachment plate and the sparger end plate attached thereto form a sparger/bracket junction by which the conduit of the feedwater sparger is connected to the feedwater sparger end bracket assembly. The feedwater sparger end bracket assembly defines a load path for transferring loads from the feedwater sparger to a reactor vessel attachment fitting attached to the reactor vessel wall and to which the feedwater sparger end bracket assembly is connected. The structural adequacy of feedwater sparger end welds and feedwater sparger end bracket assembly welds has been questioned in light of cracking identified in these welds. In particular, the weld between the attachment plate and the sparger end plate and the weld between the sparger end plate and the conduit end are primarily fillet welds, and reactor coolant can infiltrate or get between the structural components joined by these fillet welds so that the roots of the fillet welds are exposed to reactor coolant. The geometry of the fillet welds presents a crevice where corrosive products can concentrate and accumulate over time, thereby producing stress corrosion cracking.
Cracks large enough to allow significant flow of feedwater from the feedwater sparger may result in direct impingement of the relatively colder feedwater on the reactor vessel wall, causing thermal shock and cracking of the cladding on the interior surface of the reactor vessel wall. In addition, the feedwater sparger end bracket assemblies usually carry an installation preload, and this preload is undesirably compromised or lost in the event of cracking of the feedwater sparger end welds and/or the feedwater sparger end bracket assembly welds, especially in the event of cracking which results in complete detachment of the feedwater sparger end bracket assembly from the feedwater sparger. An example of feedwater sparger end bracket assemblies that have an installation preload are those associated with feedwater spargers that are sprung into place during installation, such as to maintain contact between flow baffles of the feedwater spargers and the reactor vessel wall. The flow baffles, which are ordinarily located at the feedwater nozzles in the reactor vessel, must remain essentially in contact with the reactor vessel wall to effectively eliminate thermal shock conditions at the feedwater nozzles. To assure this, the feedwater spargers are sprung into place at installation, resulting in an installation preload on each feedwater sparger end bracket assembly of about eight thousand pounds. In the event of complete weld failure causing the feedwater spargers to become completely detached from the feedwater sparger end bracket assemblies, the installation preload is lost and the feedwater spargers will not perform as designed.
Mechanical solutions to the problems of cracked feedwater sparger end welds and feedwater sparger end bracket assembly welds encounter numerous obstacles in that mechanical devices attached to the ends of the feedwater spargers and the feedwater sparger end bracket assemblies must be capable of maintaining the installation preload in the event of weld failure. Mechanical devices must be capable of balancing all loads and moments to which they are subjected, and particularly must react to the loads and moments created when there is a complete through wall crack of the feedwater sparger end welds and/or the welds of the feedwater sparger end bracket assemblies. Another deterrent to the use of mechanical devices to address the problems of weld failure in the ends of feedwater spargers and in feedwater sparger end bracket assemblies is that existing feedwater sparger end bracket assemblies often have different structural dimensions and/or components. The use of mechanical devices with feedwater sparger end bracket assemblies is thusly impeded by the difficulty involved in designing an essentially standard mechanical device for use with different feedwater sparger end bracket assemblies. A further impediment to the use of mechanical devices in response to cracking of feedwater sparger end welds and feedwater sparger end bracket assembly welds is the need for the mechanical devices to be installed using equipment or tooling operated from a location remote from the reactor vessel.
Accordingly, it is a primary object of the present invention to overcome the problems associated with cracking of feedwater sparger end welds and feedwater sparger end bracket assembly welds.
Another object of the present invention is to utilize a clamp to prevent separation of feedwater sparger end bracket assemblies.
A further object of the present invention is to utilize a clamp to prevent separation of a feedwater sparger end from a feedwater sparger end bracket assembly welded to the feedwater sparger end.
The present invention has as another object to constrain a feedwater sparger end bracket assembly from separation in horizontal, vertical and radial directions.
It is also an object of the present invention to constrain a feedwater sparger end against separation from a feedwater sparger end bracket assembly in horizontal, vertical and radial directions.
An additional object of the present invention is to avoid direct impingement of feedwater from a feedwater sparger on the reactor vessel wall in the event of cracking of a feedwater sparger end weld and/or a feedwater sparger end bracket assembly weld.
Yet another object of the present invention is to maintain the preload of a feedwater sparger end bracket assembly in the event of failure of a feedwater sparger end weld and/or a feedwater sparger end bracket assembly weld.
Still a further object of the present invention is to balance loads and moments on a clamp for a feedwater sparger end bracket assembly in the event of failure of a feedwater sparger end weld and/or a feedwater sparger end bracket assembly weld.
The present invention has as an additional object to adapt a clamp for installation on feedwater sparger end bracket assemblies of various structural dimensions and/or components.
Moreover, it is an object of the present invention to utilize a clamp to provide an alternate load path for loads from a feedwater sparger to a reactor vessel attachment fitting.
Some of the advantages of the present invention are that the clamp can be adjustably tightened on the feedwater sparger end bracket assembly; the clamp encloses the feedwater sparger end bracket assembly; the clamp holds the feedwater sparger and the feedwater sparger end bracket assembly together in the event of weld failure in any of the welds of the feedwater sparger and/or the feedwater sparger end bracket assembly; the clamp incorporates corrosion resistant materials; the clamp does not require welding to the feedwater sparger end, to the feedwater sparger end bracket assembly or to the reactor vessel; thermal shock and cracking of the cladding on the interior surface of the reactor vessel wall are avoided; the moment created on the clamp in the event of through wall cracking of a feedwater sparger end weld and/or a feedwater sparger end bracket assembly weld is balanced; shims and/or spacers can be used to easily adapt the clamp for installation on feedwater sparger end bracket assemblies having different structural dimensions and/or components; clearances between the clamp and the feedwater sparger and/or between the clamp and the feedwater sparger end bracket assembly can be limited or controlled to ensure a tight fit; proper operation of flow baffles of the feedwater spargers is maintained; the clamp may be installed remotely; and the clamp may be used on both originally installed feedwater sparger end bracket assemblies and replacement feedwater sparger end bracket assemblies.
These and other objects, advantages and benefits are realized with the present invention as generally characterized in a clamp for installation on a feedwater sparger end bracket assembly connected to a conduit of a feedwater sparger at a sparger/bracket junction in a boiling water reactor vessel. The clamp includes an upper clamp member for being assembled over a top of the feedwater sparger end bracket assembly, a lower clamp member for being assembled over a bottom of the feedwater sparger end bracket assembly and a connector securing the upper and lower clamp members to one another. The upper clamp member includes a compartment receiving an upper portion of the sparger/bracket junction, and the lower clamp member includes a compartment receiving a lower portion of the sparger/bracket junction. Each compartment comprises opposing walls constraining the sparger/bracket junction in a first direction tangential or horizontal to the boiling water reactor vessel. Each clamp member includes an inner shoulder along an inner side of the feedwater sparger end bracket assembly and an outer shoulder along an outer side of the feedwater sparger end bracket assembly for constraining the feedwater sparger end bracket assembly between the inner and outer shoulders in a second direction radial to the boiling water reactor vessel. The upper clamp member includes a lower surface along the top of the feedwater sparger end bracket assembly. The lower clamp member includes an upper surface along the bottom of the feedwater sparger end bracket assembly, and the feedwater sparger end bracket assembly is constrained between the lower surface and the upper surface in a third direction vertical to the boiling water reactor vessel. The upper clamp member further includes a recessed lower surface along the top of the conduit of the feedwater sparger, and the lower clamp member further includes a recessed upper surface along the bottom of the conduit, the conduit being constrained in the third direction between the recessed lower and upper surfaces. Each clamp member includes a shear tab positioned to be disposed between the conduit of the feedwater sparger and a wall of the boiling water reactor vessel with a close fit. The shear tab balances moments and loads to which the clamp is subjected. The upper clamp member comprises an impingement shield extending downwardly therefrom toward the lower clamp member, and the lower clamp member comprises an impingement shield extending upwardly to meet the impingement shield of the upper clamp member. The impingement shields are disposed between the sparger/bracket junction and the wall of the boiling water reactor vessel and serve to isolate the sparger/bracket junction from the wall of the boiling water reactor vessel.
A method of preventing separation of a feedwater sparger end bracket assembly connected to a conduit of a feedwater sparger at a sparger/bracket junction in a boiling water reactor vessel is generally characterized in the steps of vertically separating an upper clamp member of a clamp from a lower clamp member of the clamp, locating the upper clamp member over a top of the feedwater sparger end bracket assembly, locating the lower clamp member over a bottom of the feedwater sparger end bracket assembly, moving the upper and lower clamp members toward one another to position an upper portion of the sparger/bracket junction within a compartment of the upper clamp member and to position a lower portion of the sparger/bracket junction within a compartment of the lower clamp member, securing the upper and lower clamp members to one another, and leaving the upper and lower clamp members in place to constrain the sparger/bracket junction in a first direction, to constrain the feedwater sparger end bracket assembly in a second direction, and to constrain the feedwater sparger end bracket assembly in a third direction.
Other objects and advantages of the present invention will become apparent from the following description of a preferred embodiment taken in conjunction with the accompanying drawings, wherein like parts in each of the several figures are identified by the same reference characters.
A fragmentary portion of a conventional boiling water reactor 10 is illustrated in
A representative sparger end plate 16 is planar and is of generally rectangular peripheral configuration with the major dimension thereof also extending or oriented vertically to close off the open end of conduit 15. The sparger end plate 16 is typically attached to the end of conduit 15 by a feedwater sparger end weld 18, and the conduit end and the sparger end plate attached thereto define an end of feedwater sparger 14. The sparger end plate 16 is connected to a feedwater sparger end bracket assembly 20 which, in turn, is connected to a reactor vessel attachment fitting 21 connected, typically by welding, to reactor vessel wall 11. The feedwater sparger end bracket assembly 20 thusly couples the end of the feedwater sparger 14 to the reactor vessel 12 in spaced relation with reactor vessel wall 11. Accordingly, there is a circumferential gap or space between the feedwater sparger 14 and the reactor vessel wall 11 as best shown in
As used herein, the terms “top”, “bottom”, “upper”, “lower”, “upward” and “downward” are referenced in a vertical direction; the terms “inner” and “interior” refer to a direction toward a central longitudinal axis of the reactor vessel; the terms “outer” and “exterior” refer to a direction away from the central longitudinal axis of the reactor vessel; the terms “front” and “forward” refer to a direction away from the conduit end; the terms “back” and “rearward” refer to a direction toward the conduit end; the term “vertical” refers to the direction of the central longitudinal axis of the reactor vessel; the term “radial” refers to a direction radial to the reactor vessel wall; and the terms “horizontal” and “tangential” refer to a direction transverse or perpendicular to the vertical and radial directions.
As shown in
A representative side plate 24 has a straight rearward edge in facing abutment with a forward surface of the attachment plate 22. A weld 27 is disposed between the abutting surfaces of the side plate 24 and the attachment plate 22 and thusly connects the side plate to the attachment plate. The side plate 24 is connected to the attachment plate 22 at a location adjacent or close to the inner side edge of attachment plate 22. The side plate 24 is planar and has a generally rectangular peripheral configuration with the major dimension thereof extending vertically in the reactor vessel 12 and the minor dimension thereof extending perpendicular to the attachment plate.
Representative upper and lower bracket members 25 and 26 are also planar, and each bracket member has a straight rearward edge, a beveled forward edge, and parallel inner and outer straight side edges connecting the forward and rearward edges. The rearward edges of the upper and lower bracket members 25 and 26 are each in facing abutment with the forward surface of attachment plate 22, with the bracket members 25 and 26 being perpendicular to the side plate 24 and to the attachment plate 22. Welds 28 connect the abutting surfaces of the upper and lower bracket members 25 and 26, respectively, and the attachment plate 22. The straight inner side edge of each bracket member is in abutting relation with an outer surface of the side plate 24, and welds 29 connect the abutting surfaces of the upper and lower bracket members 25 and 26, respectively, and the side plate 24. The upper and lower bracket members 25 and 26 are parallel to and vertically spaced from one another to closely accommodate the reactor vessel attachment fitting 21 between a lower surface of the upper bracket member 25 and an upper surface of the lower bracket member 26. Accordingly, the inner side edge of upper bracket member 25 is connected to the side plate 24 at a location adjacent or close to an upper edge of side plate 24, and the inner side edge of lower bracket member 26 is connected to the side plate 24 at a location adjacent or close to a lower edge of the side plate 24.
The representative feedwater sparger end bracket assembly 20 also includes a pin 30, extending through the upper and lower bracket members 25 and 26 and through the reactor vessel attachment fitting 21, by which the feedwater sparger end bracket assembly is secured or pinned to the reactor vessel attachment fitting. The pin 30 extends in the vertical direction transverse or perpendicular to the upper and lower bracket members 25 and 26, and is inserted through aligned passages in the upper and lower bracket members and the reactor vessel attachment fitting 21. An upper end or head of the pin 30 is disposed above the upper bracket member 25 and is sized and/or configured such that the head cannot pass through the passage in the upper bracket member 25. The passages in the upper and lower bracket members 25 and 36 are ordinarily oval or elliptical in cross-section and have centers, respectively, located centrally between the inner and outer side edges of the corresponding bracket member.
A pin retainer 32 is engaged with or secured to the upper bracket member 25 and, as best seen in
A pin bail 36 of the feedwater sparger end bracket assembly 20 has a generally inverted U-shape straddling the head of pin 30. As best seen in
The reactor vessel attachment fitting 21 includes a base attached to the reactor vessel wall 11 and a nose protruding interiorly from the base in the radial direction. The nose is insertable between the upper and lower bracket members 25 and 26 when the pin 30 is removed from between the bracket members, and has a vertical dimension to fit closely between the upper and lower bracket members. A vertical passage through the nose is aligned with the aligned passages through the upper and lower bracket members 25 and 26, respectively. The pin 30 is inserted in the aligned passages, with insertion of the pin being facilitated by the pin bail 36. The pin 30 is secured in place in the aligned passages, thereby securing the feedwater sparger end bracket assembly 20 to the reactor vessel attachment fitting 21. The pin 30 may be secured in place via a threaded engagement or in any other suitable manner. The reactor vessel attachment fitting 21 can be formed integrally, unitarily with the reactor vessel wall 11 or as a separate component secured to the reactor vessel wall in any suitable manner, such as welding. The base of fitting 21 may have a curved outer end surface in abutting relation with the curved surface of the reactor vessel wall 11, and the curvature of the end surface preferably corresponds to the curvature of the reactor vessel wall. The feedwater sparger end bracket assembly 20 defines a load path for transferring loads from the feedwater sparger 14 to the reactor vessel attachment fitting 21 and the vessel wall 11.
An alternative representative feedwater sparger end bracket assembly for use with the clamp of the present invention is illustrated in
From the above, it should be appreciated that the feedwater sparger end bracket assemblies with which the clamp of the present invention may be utilized can include one or more shim plates, such as shim plate 141, to achieve proper fit of the feedwater sparger end bracket assembly with the corresponding reactor vessel attachment fitting. It should be further appreciated that proper fit of the feedwater sparger end bracket assembly with the corresponding reactor vessel attachment fitting may be achieved by varying the thickness of the attachment plate and/or the thickness of the sparger end plate, with or without the use of one or more shim plates. Where a stock thickness for the attachment plate is not sufficient to allow proper fit of the feedwater sparger end bracket assembly with the reactor vessel attachment fitting, one or more shim plates will typically be utilized to make the necessary adjustments. The radial and vertical locations of the attachment plate relative to the sparger end plate may also be varied, as needed, to obtain the proper fit. Since the reactor vessel for a typical boiling water reactor has a plurality of feedwater sparger end bracket assemblies, most typically eight feedwater sparger end bracket assemblies, it can be seen that the combined thickness of the sparger end plate and the attachment plate, including any shim plates, may vary. In other words, the thickness of the sparger/bracket junction, which includes the sparger end plate, the attachment plate and any shim plates, may not be the same for each feedwater sparger end bracket assembly of a boiling water reactor. The clamp of the present invention may be adapted for use on sparger/bracket junctions of different thicknesses, and may be used on originally installed feedwater sparger end bracket assemblies as well as replacement feedwater sparger end bracket assemblies.
The feedwater spargers of boiling water reactors may be sprung into place during installation such that there is a shear load on the feedwater sparger end welds and the feedwater sparger end bracket assembly welds. One instance in which feedwater spargers are sprung into place involves the installation of replacement feedwater spargers having flow baffles at the feedwater nozzles of the reactor vessel to eliminate thermal shock conditions at the feedwater nozzles. In order for the flow baffles to work effectively, they must remain essentially in contact with the reactor vessel wall. This is assured by the feedwater spargers being sprung into place at installation, resulting in a load on each feedwater sparger end bracket assembly of approximately 8,000 pounds. In the event of a complete through wall crack of the weld between the conduit end and the sparger end plate and/or the weld between the sparger end plate and the attachment plate, causing the feedwater sparger end bracket assembly to become completely detached from the feedwater sparger, the installation preload would be lost and the feedwater sparger would not perform as designed.
A clamp 44 for feedwater sparger end bracket assemblies is illustrated alone in
The upper clamp member 45 comprises a housing having a medial portion 48 between a forward extension 49 and a rearward extension 50 as shown in
As best shown in
The top of upper clamp member 45 has a stepped configuration with forward extension 49 protruding above the medial portion 48 and the rearward extension 50. Accordingly, the forward extension 49 has an external top wall 60 spaced upwardly from an external top wall 61 of medial portion 48 and rearward extension 50. The bottom of upper clamp member 45 has a stepped configuration so as to define a downwardly protruding inner shoulder or protrusion 62 extending downwardly from lower surface 63 and recessed lower surface 64 of upper clamp member 45, and a downwardly protruding outer shoulder or protrusion 65 extending downwardly from the lower surface 63. The lower surface 63 is at the bottom of the upper clamp member and is a forward lower surface located to the front of the opening into compartment 51. The recessed lower surface 64 is at the bottom of the upper clamp member and is a rearward lower surface located to the rear of the opening into compartment 51. The forward and rearward lower surfaces 63 and 64 are planar and parallel to one another, and are perpendicular to the internal front and rear walls 53 and 54, the internal inner side wall 55 and the impingement shield 56. Also, the forward and rearward lower surfaces 63 and 64 are parallel to internal top wall 52.
The inner shoulder 62 extends along an inner side of upper clamp member 45 in the horizontal or tangential direction and extends between the front and rear walls of compartment 51. The inner shoulder 62 has a planar outer surface 67, coextensive with internal inner side wall 55, perpendicularly joined to the forward lower surface 63 to the front of the opening into compartment 51 and perpendicularly joined to the rearward lower surface 64 to the rear of the opening into compartment 51. The outer surface 67 of inner shoulder 62 extends downwardly from the opening of compartment 51 and is perpendicular to the internal front and rear walls 53 and 54. A shim pad 66 is secured on the outer surface 67 of inner shoulder 62 and extends vertically between the rearward lower surface 64 and a bottom surface of inner shoulder 62. The shim pad 66 extends forwardly from an external rear wall of medial portion 48 to terminate at a forward edge and has a depth or thickness in the radial direction. The forward edge of shim pad 66 is spaced rearwardly from the internal front wall 53 a sufficient distance for the thickness of the sparger/bracket junction to be accommodated in the compartment 51 between the internal front and rear wall 53 and 54. As best shown in
The outer shoulder 65 extends along the horizontal extension portion of forward extension 49 parallel to inner shoulder 62 and has a planar inner surface 70 extending perpendicularly downwardly from the forward lower surface 63, the inner surface 70 being parallel to the outer surface 67 of inner shoulder 62. The outer shoulder 65 extends along the outer side of the upper clamp member opposite the inner side thereof and has a depth in the radial direction between inner surface 70 and a planar external outer surface 71 of forward extension 49. The outer surface 71 extends in a first direction, i.e. forwardly, from the compartment 51 and forms part of the external outer side wall for the upper clamp member 45. The depth of the outer shoulder 65 allows the outer shoulder to be accommodated between the lower bracket member of a feedwater sparger end bracket assembly and the reactor vessel wall as explained further below.
The radial extension portion of forward extension 49 includes a planar external forward wall 72 perpendicularly joined to a planar external inner side wall 73 of the horizontal extension portion at an inside corner. The forward wall 72 has a notch 74 therein adjacent the inside corner at which the forward wall 72 is joined to the inner side wall 73. The forward wall 72 is perpendicularly joined to the forward lower surface 63 along a lower edge of the forward extension, and the notch 74 is located along the lower edge of the forward extension. The notch 74 is open at the front and at the bottom of the radial extension portion. The inner side wall 73 of the horizontal extension portion is parallel to the inner surface 70 of outer shoulder 65 and has a cavity 75 therein of generally rectangular cross-section. The inner side wall 73 is joined to the inner surface 70 of outer shoulder 65 by the forward lower surface 63, the inner side wall 73 being joined to forward lower surface 63 along the lower edge of the forward extension. The cavity 75 is open along the inner side and bottom of the horizontal extension portion, the cavity 75 being open along a lower edge of the horizontal extension portion at which the inner side wall 73 is perpendicularly joined to the forward lower surface 63. The rearward lower surface 64 is recessed upwardly relative to the forward lower surface 63 so that the rearward lower surface 64 is recessed upwardly from the bottom surface of inner shoulder 62 a greater distance than the forward lower surface 63 is recessed upwardly from the bottom surface of the inner shoulder.
The rearward extension 50 is connected to the medial portion 48 at a curved inside corner and includes a straight horizontal segment extending rearwardly in the horizontal direction in alignment with the horizontal extension portion of forward extension 49. The horizontal segment of rearward extension 50 has an external outer side wall 77 coextensive with a downwardly protruding shear tab or protrusion 79 which protrudes downwardly from the rearward lower surface 64 along the outer side of the upper clamp member. The outer side wall 77 forms part of the external outer side wall for the upper clamp member and includes a rearward outer side wall segment along shear tab 79 and a forward outer side wall segment extending forwardly from shear tab 79 to impingement shield 56. The forward and rearward outer side wall segments are planar, with the forward outer side wall segment recessed inwardly from the rearward outer side wall segment. The shear tab 79, which is parallel to inner shoulder 62, begins at an external rear wall of the rearward extension 50 and extends forwardly therefrom along part of the horizontal or tangential length of the outer side of rearward extension 50. Accordingly, the shear tab 79 is spaced from compartment 51 in a second direction, i.e. rearwardly, opposite the direction of extension for outer shoulder 65 such that the inner shoulder 62 is located between the outer shoulder 65 and the shear tab 79 but is disposed closer to the outer shoulder than to the shear tab. The shear tab 79 has a planar outer side surface 78 formed by the rearward outer side wall segment and an inner side surface 80 parallel to the outer side surface 78. The inner side surface 80 is parallel to the outer surface 67 of inner shoulder 62 and is joined to the outer side surface 78 at a tapered lower end of the shear tab 79. The shear tab 79 has a depth or thickness in the radial direction between the outer side surface 78 and the inner side surface 80 and has a location rearward of the compartment 51 to fit between the outer side wall of the feedwater sparger conduit 15 and the reactor vessel wall 11 with a close fit as explained below.
The impingement shield 56 may be formed integrally, unitarily with the housing of the upper clamp member 45 or as a separate compartment attached to the housing in any suitable manner. The impingement shield 56 is illustrated as a separate component bolted or screwed to the housing. The impingement shield 56 extends vertically from the top of the upper clamp member 45 to a straight, horizontal lower end 82 best shown in
An internal compartment 86, best shown in
The bottom of lower clamp member 46 is defined by a planar external bottom wall. The top of lower clamp member 46 has a stepped configuration defining an upwardly protruding inner shoulder or protrusion 94 extending upwardly from planar upper surface 95 and planar recessed upper surface 96, and an upwardly protruding outer shoulder or protrusion 97 extending upwardly from the upper surface 95. The upper surface 95, which is at the top of the lower clamp member, is located to the front of the opening into compartment 86 and is a forward upper surface. The recessed upper surface 96 is located to the rear of the opening into compartment 86 at the top of the lower clamp member and is a rearward upper surface. The forward upper surface 95 corresponds to the forward lower surface 63 and is parallel to and vertically aligned with the forward lower surface 63. The rearward upper surface 96 corresponds to the rearward lower surface 64 and is parallel to and vertically aligned with the rearward lower surface 64.
The inner shoulder 94 is similar to the inner shoulder 62 and is vertically aligned with the inner shoulder 62. The inner shoulder 94 extends along the inner side of lower clamp member 46 in the tangential or horizontal direction between the front and rear walls of compartment 86 and has a planar outer surface 98 coextensive with internal inner side wall 90, the outer surface 98 being perpendicular to the internal front and rear walls 88 and 89. The outer surface 98 of inner shoulder 94 is perpendicularly joined to forward upper surface 95 to the front of the opening of compartment 86 and is perpendicularly joined to rearward upper surface 96 to the rear of the opening into compartment 86. The outer surface 98 extends upwardly from the opening of compartment 86 and is co-planar with the outer surface 67 of the inner shoulder 62. A shim pad 66 is secured on the outer surface 98 as described above for the upper clamp member 45 and is located at a location corresponding to the shim pad 66 of the upper clamp member. The shim pad 66 of the lower clamp member 46 thusly extends vertically between the rearward upper surface 96 and a top surface of inner shoulder 94. A spacer 68, shown in
The outer shoulder 97 is similar to the outer shoulder 65 and is vertically aligned with the outer shoulder 65. The outer shoulder 97 extends along the horizontal extension portion of forward extension 84 parallel to the inner shoulder 94 and has a planar inner surface 99 extending perpendicularly upwardly from the forward upper surface 95. The inner surface 99 of outer shoulder 97 is parallel to the outer surface 98 of inner shoulder 94, and is co-planar with the inner surface 70 of the outer shoulder 65 of the upper clamp member 45. The outer shoulder 97 extends along the outer side of the lower clamp member in the forward direction from compartment 86, and has a depth in the radial direction between inner surface 99 and a planar external outer surface 100 of the forward extension 84. The outer surface 100 forms part of the external outer side wall for the lower clamp member. The top of outer shoulder 97 and the bottom of outer shoulder 65 may have beveled or chamfered edges.
The radial extension portion of forward extension 84 includes a planar external forward wall 101 joined to a planar external inner side wall 102 of the horizontal extension portion by an angled corner wall. The forward wall 101, the corner wall and the inner side wall 102 are perpendicularly joined to the forward upper surface 95 along an upper edge of the forward extension 84. The rearward upper surface 96 is recessed downwardly relative to the forward upper surface 95 so that the rearward upper surface 96 is recessed downwardly from the top surface of inner shoulder 94 a greater distance than the forward upper surface 95 is recessed downwardly from the top surface of the inner shoulder 94.
The rearward extension 85 is similar to rearward extension 50 and is vertically aligned with the rearward extension 50. The rearward extension 85 has a horizontal segment corresponding to the horizontal segment of rearward extension 50 and has an external outer side wall 103 coextensive with an upwardly protruding shear tab or protrusion 105. The outer side wall 103 forms part of the external outer side wall for the lower clamp member and includes a rearward outer side wall segment along shear tab 105 and a forward outer side wall segment extending forwardly from shear tab 105 to impingement shield 91, with the forward outer side wall segment being recessed inwardly from the rearward outer side wall segment. Shear tab 105 is similar to shear tab 79 and protrudes upwardly from the rearward upper surface 96, the shear tab 105 being disposed at a location corresponding to the location of shear tab 79. Accordingly, the shear tab 105 is spaced from compartment 86 in the rearward direction, opposite the direction of extension for outer shoulder 97, such that the inner shoulder 94 is located between the outer shoulder 97 and the shear tab 105 but is disposed closer to the outer shoulder 97 than to the shear tab 105. The shear tab 105 has a planar outer side surface 104 formed by the rearward outer side wall segment of outer side wall 103 and has an inner side surface 106 parallel to the outer side surface 104. The inner side surface 106 is parallel to the outer surface 98 of inner shoulder 94 and is joined to the outer side surface 104 at a tapered upper end for the shear tab 105 as described for the shear tab 79. The outer side surface 104 of shear tab 105 is co-planar with the outer side surface 78 of shear tab 79. The inner side surface 106 of shear tab 105 is co-planar with the inner side surface 80 of shear tab 79.
The impingement shield 91 is similar to impingement shield 56 and extends in the vertical direction from the bottom of the lower clamp member 46 to a straight, horizontal upper end 107 best shown in
The clamp 44 is preferably fabricated primarily from Austenitic 300 series stainless steel. If additional material strength is needed for certain components, XM-19 stainless steel may be used. In a preferred embodiment, the upper and lower clamp members each have a maximum horizontal or tangential dimension of about 16.60 inches and a maximum radial dimension of about 7.75 inches. The upper clamp member has a maximum vertical dimension or height of about 8.00 inches, and the lower clamp member has a maximum vertical dimension or height of about 6.5 inches. The connector is about 1.25 inches in diameter with seven threads per inch and is about 15 inches long including the head thereof.
A method of preventing separation of feedwater sparger end bracket assemblies involves installing the clamp assembly 44 on a feedwater sparger end bracket assembly, such as feedwater sparger end bracket assembly 20, with the clamp being lowered into the reactor vessel 12 using remote tooling. The upper and lower clamp members are moved away from one another and are separated vertically to the extent required to obtain an open position for the clamp, allowing the clamp members to fit over the feedwater sparger and the feedwater sparger end bracket assembly. The upper clamp member 45 is disposed over the top of the sparger/bracket junction, and the lower clamp member 46 is disposed below the sparger/bracket with the connector 47 located interiorly of the feedwater sparger 14 and the feedwater sparger end bracket assembly 20. Accordingly, the upper and lower clamp members will be disposed in opposition to one another over the feedwater sparger end bracket assembly. An upper portion of the sparger/bracket junction, i.e. upper portions of sparger end plate 16 and attachment plate 22 which protrude upwardly beyond the conduit 15 and the upper bracket member 25, is aligned with the internal compartment 51 of the upper clamp member 45. A lower portion of the sparger/bracket junction, i.e. lower portions of sparger end plate 16 and attachment plate 22 which protrude downwardly beyond the conduit 15 and the lower bracket member 26, is aligned with the internal compartment 86 of lower clamp member 46. Of course, where the sparger/bracket junction includes a shim plate, an upper portion of the shim plate will be aligned with compartment 51 and a lower portion of the shim plate will be aligned with compartment 86. The connector 47 is then threaded into the lower clamp member, and the connector 47 and/or another tool is used to move the upper and lower clamp members 45 and 46 toward one another. The upper and lower clamp members 45 and 46 are drawn together to obtain the closed position in which the clamp members enclose the upper and lower portions of the sparger/bracket junction. The upper and lower clamp members are securely tightened on the feedwater sparger 14 and the feedwater sparger end bracket assembly 20, and are held in place via the connector 47. The clamp 44 will then be in a closed position with the lower end 82 of impingement shield 56 in overlapping engagement with the upper end 107 of impingement shield 91. The clamp is then left in place in the reactor vessel 12.
The sparger/bracket junction is constrained in a second or vertical direction due to constraint of the sparger end plate 16 and the attachment plate 22 between the internal top wall 52 of the upper clamp member 45 and the internal bottom wall 87 of the lower clamp member 46. The upper and lower bracket members 25 and 26 are constrained in the vertical direction with a close fit between the forward lower surface 63 of the upper clamp member 45 and the forward upper surface 95 of the lower clamp member 46. The feedwater sparger conduit 15 is constrained in the vertical direction with a close fit between the rearward lower surface 64 of upper clamp member 45 and the rearward upper surface 96 of lower clamp member 46. Accordingly, separation of the feedwater sparger end bracket assembly is prevented in the vertical direction.
The outer shoulder 65 of upper clamp member 45 is disposed between the upper bracket member 25 and the reactor vessel wall 11, with the inner surface 70 of outer shoulder 65 disposed adjacent the outer side edge of the upper bracket member with little or no clearance. The shear tab 79 of the upper clamp member 45 is disposed between the conduit 15 and the reactor vessel wall 11 with a close fit, the inner side surface 80 of the shear tab 79 being adjacent the outer side wall of the conduit with little or no clearance therebetween. The outer shoulder 97 of the lower clamp member 46 is disposed between the lower bracket member 26 and the reactor vessel wall 11, with the inner surface 99 of the outer shoulder 97 adjacent the outer side edge of the lower bracket member with little or no clearance therebetween. The shear tab 105 of the lower clamp member 46 is disposed between the conduit 15 and the reactor vessel wall 11 with a close fit, with the inner side surface 106 of the shear tab 105 adjacent the outer side wall of the conduit with little or no clearance therebetween. The outer surface 67 of inner shoulder 62 of the upper clamp member 45 is adjacent the inner side edge of attachment plate 22 with minimal or no clearance therebetween to establish a tight fit between the upper clamp member and the feedwater sparger end bracket assembly. The shim pad 66 of the upper clamp member 45 fills the gap or space between the outer surface 67 and the inner side wall of conduit 15 to establish a tight fit between the upper clamp member and the feedwater sparger. The spacer 68 of the upper clamp member 45 occupies the gap or space between the outer surface 67 and the inner side edge of the sparger end plate 16 as shown in
The impingement shields 56, 91 are disposed between the sparger/bracket junction and the reactor vessel wall 11. The impingement shields 56, 91 isolate the sparger/bracket junction from the vessel wall 11 and prevent direct impingement of feedwater flow on the reactor vessel wall 11 should a through wall crack develop between the conduit 15 and the sparger end plate 16. Accordingly, direct impingement of relatively colder feedwater on the reactor vessel wall 11 with concomitant thermal shock and cracking of the cladding on the interior surface of the reactor vessel wall is avoided. The shear tabs 79, 105 assist in carrying moment on the clamp 44 that occurs in the event of a complete through wall crack of the welds between the conduit 15 and the sparger end plate 16 or between the sparger end plate 16 and the attachment plate 22. In the event that the feedwater spargers are sprung into place such that there is a shear preload on the welds, the preload is maintained by the clamp 44 in the event of weld failure. If either of the welds between the conduit 15 and the sparger end plate 16 or between the sparger end plate 16 and the attachment plate 22 fails, the load from the feedwater sparger is transferred to the clamp 44 at location A shown in
Various shims and spacers can be incorporated in the clamp 44 to achieve a tight fit between the clamp and the feedwater sparger and/or the feedwater sparger end bracket assembly, as needed. Various shims and spacers can be incorporated in the clamp 44 to adapt the clamp for installation on feedwater sparger end bracket assemblies having various dimensions and components. The clamp can be installed on feedwater sparger end bracket assemblies having one or more shim plates, such as feedwater sparger end bracket assembly 120, by forming the internal compartments 51, 86 with a distance between the internal front walls and the internal rear walls sufficient to accommodate the sparger end plate, the attachment plate, and any shim plate. A clamp designed for installation on feedwater sparger end bracket assembly 120 can also be installed on the feedwater sparger end bracket assembly 20 by using shims and/or spacers to achieve a close fit between the feedwater sparger end bracket assembly 20 and the clamp. It should be appreciated, therefore, that the clamp 44 can be used on sparger/bracket junctions of different thicknesses. The shims and/or spacers can be incorporated in the clamp at any suitable locations.
The clamp 44 positively secures to the feedwater sparger end bracket assembly and holds the feedwater sparger and the feedwater sparger end bracket assembly together in the event of through wall cracking of any or all feedwater sparger and/or feedwater sparger end bracket assembly welds. The clamp prevents separation of the feedwater sparger end bracket assembly in first, second and third directions, i.e. horizontal or tangential, vertical and radial directions. The clamp prevents separation of the feedwater sparger end bracket assembly from the feedwater sparger and prevents separation of the structural components of the feedwater sparger end bracket assembly. The clamp provides an alternate load path for loads from the feedwater sparger to the reactor vessel attachment fitting, and the outer shoulders and shear tabs provide an alternate path for transferring loads from the feedwater sparger to the reactor vessel attachment fitting. The clamp can be installed remotely from a refueling bridge using long-handled tooling. The clamp incorporates corrosion resistant materials and does not require welding to the feedwater sparger, the feedwater sparger end bracket assembly or to the reactor vessel.
In as much as the present invention is subject to many variations, modifications and changes in detail, it is intended that all subject matter discussed above or shown in the accompanying drawings be interpreted as illustrative only and not be taken in a limiting sense.
Butler, Patrick J., McCurdy, H. William
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